F5OEO-librpitx/app/testrpitx.cpp

#include <unistd.h>
#include "../src/librpitx.h"
#include <unistd.h>
#include "stdio.h"
#include <cstring>
#include <signal.h>

bool running=true;
/*int 
gcd ( int a, int b )
{
  int c;
  while ( a != 0 ) {
     c = a; a = b%a;  b = c;
  }
  return b;
}*/

uint64_t gcd(uint64_t x,uint64_t y)
{
	return y == 0 ? x : gcd(y, x % y);
}

uint64_t lcm(uint64_t x, uint64_t y)
{
	return x * y / gcd(x, y);
}

void SimpleTest(uint64_t Freq)
{
	generalgpio genpio;
	fprintf(stderr,"GPIOPULL =%x\n",genpio.gpioreg[GPPUDCLK0]);
	
	#define PULL_OFF 0
    #define PULL_DOWN 1
    #define PULL_UP 2
	genpio.gpioreg[GPPUD]=1;//PULL_DOWN;
    usleep(150);
    genpio.gpioreg[GPPUDCLK0]=(1<<4); //GPIO CLK is GPIO 4
    usleep(150);
    genpio.gpioreg[GPPUDCLK0]=(0); //GPIO CLK is GPIO 4
	
	//genpio.setpulloff(4);

	padgpio pad;
	pad.setlevel(7);


	clkgpio clk;
	clk.print_clock_tree();
	clk.SetPllNumber(clk_plla,0);
	
	//clk.SetAdvancedPllMode(true);
	//clk.SetPLLMasterLoop(0,4,0);
	//clk.Setppm(+7.7);
	clk.SetCenterFrequency(Freq,1000);
	double freqresolution=clk.GetFrequencyResolution();
	double RealFreq=clk.GetRealFrequency(0);
	fprintf(stderr,"Frequency resolution=%f Error freq=%f\n",freqresolution,RealFreq);
	int Deviation=0;
	clk.SetFrequency(000);
	
	clk.enableclk(4);
	usleep(100);
	//clk.SetClkDivFrac(100,0); // If mash!=0 update doesnt seem to work
	int count=0;
	while(running)
	{
		//clk.SetMasterMultFrac(44,(1<<count));
		//uint32_t N=(1<<18);
		uint32_t N=(1<<13)*count;

		//clk.SetMasterMultFrac(34,N);
		printf("count =%d gcd%d spurious%f N=%x %f\n",count,lcm(N,1<<20),(double)gcd(1<<20,N)*19.2e6/(double)(1<<20),N,N/(float)(1<<20));
		count=(count+1)%128;
		//usleep(10000000);
		int a=getc(stdin);
		static int Ki=4,Kp=0,Ka=0;
		Kp=Kp+1;
		if(Kp>15)
		{ Kp=0;
		 Ki=Ki+1;	
		}
		//Ki=Ki+1;
		if(Ki>11)
		{
			 Ki=4;
			 Ka++;
		}
		Ki=Kp;
		
		clk.SetClkDivFrac(count,count);
		
		//clk.SetPLLMasterLoop(Ki,4,Ka);
		//clk.SetPLLMasterLoop(2,4,0);
		//clk.SetPLLMasterLoop(3,4,0); //best one
		
		//printf("Ki=%d :Kp %d Ka %d\n ",Ki,Kp,Ka);
		/*clk.SetFrequency(000);
		sleep(5);
		clk.SetFrequency(freqresolution);
		sleep(5);*/
	}
	/*
	for(int i=0;i<100000;i+=1)
	{
		clk.SetFrequency(0);
		usleep(1000);
	}*/
	clk.disableclk(4);
	
}

void SimpleTestDMA(uint64_t Freq)
{
	

	int SR=1000;
	int FifoSize=4096;
	ngfmdmasync ngfmtest(Freq,SR,14,FifoSize);
	for(int i=0;running;)
	{
		//usleep(10);
		usleep(FifoSize*1000000.0*3.0/(4.0*SR));
		int Available=ngfmtest.GetBufferAvailable();
		if(Available>FifoSize/2)
		{	
			int Index=ngfmtest.GetUserMemIndex();
			//printf("GetIndex=%d\n",Index);
			for(int j=0;j<Available;j++)
			{
				//ngfmtest.SetFrequencySample(Index,((i%10000)>5000)?1000:0);
				ngfmtest.SetFrequencySample(Index+j,(i%SR)/10.0);
				i++;
			
			}
		}
		
		
	}
	fprintf(stderr,"End\n");
	
	ngfmtest.stop();
	
}


void SimpleTestFileIQ(uint64_t Freq)
{
	FILE *iqfile=NULL;
	iqfile=fopen("../ssbtest.iq","rb");
	if (iqfile==NULL) printf("input file issue\n");

	#define IQBURST 1280
	bool stereo=true;
	int SR=48000;
	int FifoSize=512;
	iqdmasync iqtest(Freq,SR,14,FifoSize);
	short IQBuffer[IQBURST*2];
	std::complex<float> CIQBuffer[IQBURST];	
	while(running)
	{
		int nbread=fread(IQBuffer,sizeof(short),IQBURST*2,iqfile);
		if(nbread>0)
		{
			for(int i=0;i<nbread/2;i++)
			{
					
				CIQBuffer[i]=std::complex<float>(IQBuffer[i*2]/32768.0,IQBuffer[i*2+1]/32768.0); 
				
			}
			iqtest.SetIQSamples(CIQBuffer,nbread/2,1);
		}
		else 
		{
			printf("End of file\n");
			fseek ( iqfile , 0 , SEEK_SET );
		
		
		}
	}

	iqtest.stop();
}

void SimpleTestbpsk(uint64_t Freq)
{
	
	
	clkgpio clk;
	clk.print_clock_tree();
	int SR=100000;
	int FifoSize=1024;
	int NumberofPhase=2;
	phasedmasync biphase(Freq,SR,NumberofPhase,14,FifoSize);
	int lastphase=0;
	while(running)
	{
		//usleep(FifoSize*1000000.0*1.0/(8.0*SR));
		usleep(10);
		int Available=biphase.GetBufferAvailable();
		if(Available>256)
		{	
			int Index=biphase.GetUserMemIndex();
			
				
				for(int i=0;i<Available;i++)
				{
					int phase=(rand()%NumberofPhase);
					biphase.SetPhase(Index+i,phase);
				}
				/* 					
				for(int i=0;i<Available/2;i++)
				{
					int phase=2*(rand()%NumberofPhase/2);
					biphase.SetPhase(Index+i*2,(phase+lastphase)/2);
					biphase.SetPhase(Index+i*2+1,phase);
					lastphase=phase;
				}*/
				/*for(int i=0;i<Available;i++)
				{
					lastphase=(lastphase+1)%NumberofPhase;
					biphase.SetPhase(Index+i,lastphase);
				}*/
			
		}
	}
	biphase.stop();
}


void SimpleTestSerial()
{
	
	bool stereo=true;
	int SR=10000;
	int FifoSize=1024;
	bool dualoutput=true;
	serialdmasync testserial(SR,14,FifoSize,dualoutput);
	
	while(running)
	{
		
		usleep(10);
		int Available=testserial.GetBufferAvailable();
		if(Available>256)
		{	
			int Index=testserial.GetUserMemIndex();
			
				
				for(int i=0;i<Available;i++)
				{
					
					
					testserial.SetSample(Index+i,i);
					
				}
			
		}
	}
	testserial.stop();
}

void SimpleTestAm(uint64_t Freq)
{
	FILE *audiofile=NULL;
	audiofile=fopen("../ssbaudio48.wav","rb");
	if (audiofile==NULL) printf("input file issue\n");


	bool Stereo=true;
	int SR=48000;
	int FifoSize=512;
	amdmasync amtest(Freq,SR,14,FifoSize);
	
	short AudioBuffer[128*2];

	while(running)
	{
		//usleep(FifoSize*1000000.0*1.0/(8.0*SR));
		usleep(100);
		int Available=amtest.GetBufferAvailable();
		if(Available>256)
		{	
			int Index=amtest.GetUserMemIndex();
			int nbread=fread(AudioBuffer,sizeof(short),128*2,audiofile);
			if(nbread>0)
			{
				
				for(int i=0;i<nbread/2;i++)
				{
					if(!Stereo)
					{
						float x=((AudioBuffer[i*2]/32768.0)+(AudioBuffer[i*2+1]/32768.0))/4.0;
						amtest.SetAmSample(Index+i,x);
					}
					else
					{
						float x=((AudioBuffer[i]/32768.0)/2.0)*8.0;
						amtest.SetAmSample(Index+i,x);
						
					}
					
				}
			}
			else 
			{
				printf("End of file\n");
				fseek ( audiofile , 0 , SEEK_SET );
				//break;
			}
		}
	}
	amtest.stop();
}

void SimpleTestOOK(uint64_t Freq)
{
	
	int SR=2000;
	int FifoSize=512;
	amdmasync amtest(Freq,SR,14,FifoSize);
	
	
	int count=0;
	int Every=SR/100;
	float x=0.0;
	
	while(running)
	{
		//usleep(FifoSize*1000000.0*1.0/(8.0*SR));
		usleep(1);
		int Available=amtest.GetBufferAvailable();
		if(Available>256)
		{	
				int Index=amtest.GetUserMemIndex();			
				for(int i=0;i<Available;i++)
				{
						
						if(count<1000)
							x=0;
						else
							x=1.0;
						amtest.SetAmSample(Index+i,x);
						count++;
						if(count>2000) count=0;
				}	
		}
	}
	amtest.stop();
}

void SimpleTestBurstFsk(uint64_t Freq)
{
	
	//int SR=40625;
	int SR=40625;
	float Deviation=26370;
	int FiFoSize=4000;
	fskburst fsktest(Freq,SR,Deviation,14,FiFoSize);
	
	unsigned char TabSymbol[FiFoSize];
	int BurstSize=100;
	
	while(running)
	{
		int i;
		int BurstLen=rand()%FiFoSize;
		for(i=0;i<BurstLen;i++)
		{
			TabSymbol[i]=rand()%2;
		}	
		fsktest.SetSymbols(TabSymbol,BurstLen);
		sleep(1);
		/*for(i=0;i<FiFoSize;i++)
		{
			TabSymbol[i]=1;
		}	
		fsktest.SetSymbols(TabSymbol,FiFoSize);
		sleep(1);*/
		
		
	}
	fsktest.stop();
}
static void
terminate(int num)
{
    running=false;
	fprintf(stderr,"Caught signal - Terminating\n");
   
}


int main(int argc, char* argv[])
{
	
	uint64_t Freq=144200000;
	if(argc>1)
		 Freq=atol(argv[1]);

	 for (int i = 0; i < 64; i++) {
        struct sigaction sa;

        std::memset(&sa, 0, sizeof(sa));
        sa.sa_handler = terminate;
        sigaction(i, &sa, NULL);
    }

	SimpleTest(Freq);
	//SimpleTestbpsk(Freq);
	//SimpleTestFileIQ(Freq);
	//SimpleTestDMA(Freq);
	//SimpleTestAm(Freq);
	//SimpleTestOOK(Freq);
	//SimpleTestBurstFsk(Freq);
	
}